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MTest Facility Low Energy Beam Erik Ramberg AEM 15 October, 2007. Many thanks to Pier!!. New Capabilities of Meson Test Beam. Accelerator Division has completed the update of the MTest beamline: - PowerPoint PPT Presentation
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New Capabilities of Meson Test Beam
• Accelerator Division has completed the update of the MTest beamline:– A new movable target was installed only 700’ upstream of the user test areas to
increase low energy beam rates. The new beamline downstream of that includes 13 relocated magnets, 11 new elements, additional shielding, and movement of the beamline transversely in the tunnel.
– The original upstream target was additionally put on a mover so that better primary focusing could be obtained for the downstream target.
– Scintillating fiber plane monitors have been installed and debugged.– Stable low current power supplies and Hall probes were installed for better
control of magnets at low current.– A 1/4” movable lead sheet was installed at the focal point to reduce electron
rates when needed.
• Previous test beam was limited to 4 GeV and above. The current test beam has delivered electrons down to 0.5 GeV.
• New calorimetry and time-of-flight monitors were installed in the user areas. A new differential Cerenkov counter is being installed now, and a pixel telescope in the winter.
• In July, taking one day away from a user request, we did a low energy scan to determine rates and beam composition.
Meson Test Beam FacilityMovable upstream 25 cm Al target Movable downstream 30cm target location
Mtest secondary beamline
MTest Beam Layout and Modes
Proton Mode: 120 GeV protons
transmitted through upstream target
Proton Mode: 120 GeV protons
transmitted through upstream target
Pion Mode: 8-66 GeV beam tuned for
secondaries from upstream target
Pion Mode: 8-66 GeV beam tuned for
secondaries from upstream target
Low Energy Pion Mode: 1-32 GeV beam tuned for
secondaries from downstream target
Low Energy Pion Mode: 1-32 GeV beam tuned for
secondaries from downstream target
• New differential Cerenkov detector can resolve beam composition at entrance to hall:
• Lead glass calorimeter at end of user area can resolve beam composition there.
• Time-of-flight system works below 4 GeV:
No lead in beamline
With lead in beamline
Electron peak resolution in lead glass is ~6% at 8 GeV with collimators wide open
Beam Energy (GeV)
Rate at Entrance to Facility (per spill)
Rate at Exit of Facility (per spill)
%Pions, Muons**
% Electrons**
16 132,000 95,000 82% 18%
8 89,000 65,000 42% 58%
4 82,000 51,000 26% 72%
2 88,000 38,000 34% 65%
1 79,000 23,000 <50% >50%
Beam Energy (GeV)
Rate at Entrance to Facility (per spill)
Rate at Exit of Facility (per spill)
%Pions, Muons**
% Electrons**
16 86,000 59,000 100% 0%
8 31,000 18,000 95% 5%
4 5,400 1,300 73% 16%
2 6,000 480 51% 42%
1 5,000 120 ~60% ~40%
Rates* without lead scatterer
Rates* with lead scatterer
*Rates here are normalized to 1E11 at MW1SEM
**Measured at exit of facility with PbG calorimeter
• T970 is an ILC hadron calorimeter, with RPC active planes and digital pad readout
• At 2 GeV, they placed extra iron in front of their calorimeter to absorb all pions.
• They showed that about 2/3 of the particles entering their calorimeter were muons and 1/3 pions.
• This is first evidence for a beam at this low of an energy.
• Will attempt to duplicate this at 1 GeV.
Muon vs pions at 2 GeV -
preliminary results from T970
Beam profiles measured with MWPC station 1
16 GeV profiles 2 GeV profiles
- We clearly need to focus on focusing.
2.5 x 2.5 meter MINERvA test detectorPlanned for Summer, 2008
In secondary beamIn secondary beam
In tertiary beamIn tertiary beam
Requests 300 MeV beam!Requests 300 MeV beam!
Doug Jensen will be overseeing this installation
Tail Catcher
ECALECAL
HCALHCAL
Electronic Racks
Beam
Example of CALICE Setup at MTBF
Starting to write MOU now. Interference with MINERVA?
Can Fermilab Test Beam simulate ILC structure?
Possible path to ILC beam structure:• Fill Main Injector with 4 Booster batches,
with 19 nsec RF structure.• Turn on already existing 2.5 MHz
coalescing cavities. This results in a 400 nsec particle bunch spacing, with gap after 4 buckets.
• Implement a shorter partial extraction cycle (‘ping’) using current quadrupole resonance magnet.
• Fit 5 of these pings in a 1 second spill
x100x100. . .. . .
1 second1 second